Schmidt amines from carboxylic

Schiff bases s. Azomethines Schlotterbeck s. Buchner Schmidt reaction 17, 524 —, amines from carboxylic acids 19, 305 20, 366 —, lactams from ketones, cyclic, ring expansion... 

Schmidt reaction Amines from carboxylic acids... 

Amines from carboxylic acids Schmidt reaction... 

The Schmidt reaction of carboxylic acids with hydrazoic acid has the advantage over Curtius rearrangement that it is only one step from the acid to the amine, but the conditions are more drastic (usually sulphuric acid plus sodium azide). Under these harsh conditions, the isocyanate intermediate is rarely isolated. For these reasons, the Curtius rearrangement is frequently employed to convert acids to amines. The Schmidt reaction of ketones with hydrazoic acid is a powerful method for the synthesis of amides and lactams. TTiis process is somewhat related to the Beckmann rearrangement of oximes however, the Schmidt reaction is more succinct, allowing the conversion of ketones to amides in a single operation. Considering its widespread... 

The Curtius, Hofmann (see p. 267), and Schmidt (see p. 307) reactions are in that order decreasingly mild, decreasingly flexible, and increasingly expeditious. The last-named quality varies somewhat with the available starting material, whether the free acid or the ester. The Curtius reaction lends itself to the preparation of isocyanates, sym-and 08-ureas, amides, urethans, and amines at will, and provides a wide choice of experimental conditions. For synthetic purposes the Hofmann reaction can be used only to prepare sym-ureas, urethans, and amines directly, and halting the reaction at a desired intermediate is often not possible. The variety of experimental conditions is narrower and more limited. The Schmidt reaction on carboxylic acids or derivatives has been applied as a preparative method only to the production of amines although urethans and isocyanates have been prepared occasionally by this reaction, it can hardly be considered a preparative method for them. Amides can be prepared by the Schmidt reaction only from ketones. The choice of experimental conditions employable in the Schmidt reaction is narrow. 

There are actually three reactions called by the name Schmidt reaction, involving the addition of hydrazoic acid to carboxylic acids, aldehydes and ketones, and alcohols and alkenes. The most common is the reaction with carboxylic acids, illustrated above.Sulfuric acid is the most common catalyst, but Lewis acids have also been used. Good results are obtained for aliphatic R, especially for long chains. When R is aryl, the yields are variable, being best for sterically hindered compounds like mesi-toic acid. This method has the advantage over 18-13 and 18-14 that it is just one laboratory step from the acid to the amine, but conditions are more drastic. Under the acid conditions employed, the isocyanate is virtually never isolated. 

Scheme 10.38. A representation of the Schmidt rearrangement showing that the amine prepared from the corresponding carboxylic acid retains the absolute configuration of the acid (see Schmidt, R. F. Angew. Chem., 1923, 36, 511 Schemit, R. F. Chem. Ber., 1924, 57, 704 Benson, R. F. Chem. Rev., 1947, 41,1).

The reactions of HN3 with cyclic alcohols to yield mixtures of ketones, amines, and products with an enlarged ring are catalyzed by H2SO4 [1]. Tertiary alcohols are converted to azides in the presence of acid [12] or TiCU [13]. Aldehydes and ketones with HN3 undergo a Schmidt-type reaction by liberating N2 and inserting NH In the presence of H or Lewis acids [14]. Ketones yield secondary amides and, in the case of cyclic ketones, lactames. Aldehydes are converted to nitriles or N-formylamines. Tetrazole derivatives result with excess HN3 [1, 15]. However, a-azido ethers are obtained from aldehydes and HN3 in the presence of alcohols by catalysis of TiC [16]. Carboxylic acids and anhydrides form amines, N2, and CO2 in Schmidt reactions with HN3. Intermediates are carbamic acids which form by insertion of NH into the R-COOH bond [1, 14]. High yields result for acids of arenes [17]. 

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